Heat Exchanger Tank and Related Methods and Apparatuses

ABSTRACT

A heat exchanger (such as a radiator) that provides for a consistent tank-to-header joint location. The tank generally includes at least two indentations and at least one isolator having a base at least partially disposed in one of the indentations and a coupler extending from the base for coupling the tank to at least one other component of the heat exchanger.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of copending U.S. patentapplication Ser. No. 12/779,946, filed May 13, 2010, which is hereinincorporated by reference in its entirety.

BACKGROUND

1. Field of the Disclosure

The present disclosure generally relates to the field of heat exchangersincluding aluminum heat exchangers used to cool internal combustionengines.

2. Brief Description of Related Art

Heat exchangers are used to transfer thermal energy from one medium toanother. For example, in an internal combustion engine coolingapplication, heat is transferred from the internal combustion engine tothe cooling fluid and the cooling fluid is itself cooled as its heat istransferred to the atmosphere when the coolant flows through a radiator.The coolant flow to and from the radiator may be pumped, and a fan maybe provided in the proximity of the radiator to blow air through theradiator. In any event, the coolant flow and corresponding coolingprocess continues during operation of the internal combustion engine,thereby maintaining the operating temperature of the internal combustionengine within acceptable limits and preventing the engine fromoverheating.

At present, aluminum radiators are less expensive to manufacture in highvolumes than copper or brass radiators, but tend to be less durable. Atypical heat exchanger or radiator includes a manifold assembly thatconducts fluid flow through a plurality of flow tubes or exposed pipes(often with fins or other means for cooling increasing surface area) toreduce the operating temperature of the internal combustion engine. Amanifold assembly typically includes a tank and a header joinedtogether. Furthermore, current aluminum compact heat exchanger designsthat use aluminum tanks either require the use of aluminum sidebracketsor secondary machining operations to use steel sidebrackets. Thealuminum sidebrackets furthermore tend to lack the strength and costadvantages of the steel sidebrackets that are commonly used on copperand brass radiators.

More particularly, current aluminum compact heat exchanger designsutilize a variety of tanks—plastic tanks, formed tanks, fabricatedtanks, or cast tanks. Plastic tanks are mainly used for mass production,but may not be cost effective for production levels below about 100,000units per year. A formed tank, on the other hand, does not provide forready assembly to the sidebrackets. Therefore, sidebrackets aregenerally welded or brazed to the core or the tank and, hence, are oftenmade of aluminum, which is more expensive and weaker than steel.Fabricated tanks may not be cost effective for production quantitiesover about 500 units per year.

However, current cast tank designs fail in creating an interchangeabletank that has a consistent tank-to-header seam location whenever such atank is mounted on a header. One reason for such inconsistenttank-to-header seam location is the inconsistent core height growthduring the core baking process (i.e., during the fin-to-tube andtube-to-header brazing process). This inconsistent tank-to-header seamlocation results in variations in tank-to-header welding locations foreach tank-header pair and, hence, makes it difficult to use roboticwelding to attach the tanks to the headers. Misaligned or improperlyseated tanks, furthermore, are undesirable because they can result inleaks after the tank is welded to the header.

Even in the case where aluminum sidebrackets are used, problems couldarise when such sidebrackets are welded to the core or tanks of the heatexchanger. Such welded sidebrackets may fail to accommodate thermalexpansions (of the core or the tanks) that occur, for example, duringwelding or brazing or even under normal operating conditions. When noadequate means are provided to accommodate thermally expanding metals,damage to the core may result in the case where such welded aluminumsidebrackets are utilized.

Therefore, it is desirable to provide an all aluminum (or aluminumalloy) industrial heat exchanger (i.e., radiator) that providesconsistency in tank-to-header joint locations to better allow for theuse of robotic welding to attach tanks to headers.

It is also desirable that a heat exchanger include a cast tankmanufactured from aluminum or aluminum alloy and be suitable for roboticwelding without the need for machining the tank.

It is further desirable to devise a sidebracket mounting mechanism for aradiator that permits the use of stronger steel sidebrackets on analuminum core, while allowing for thermal expansion of the core withoutthe need for machining the tank.

SUMMARY

In one embodiment, the present disclosure relates to a cast tank to beused as part of a heat exchanger, and a method of forming such a casttank. The cast tank comprises an elongate aluminum housing having asubstantially U-shaped cross section. The housing includes: a pair oflonger side panels having a length and a pair of ends, wherein eachlonger side panel has a first outer surface and a first inner surface; atop panel; a pair of shorter side panels having a length that is shorterthan the length of the longer side panels and a pair of ends whereineach shorter side panel has a second outer surface and a second innersurface and each end of each shorter side panel meets an end of one ofthe longer side panels forming a juncture; and an indentation at eachend of the top panel (e.g., at the juncture of the pair of longer sidepanels and the pair of shorter side panels). In one embodiment, theindentation may be approximately T-shaped. In the cast tank, portions ofeach first inner surface and each second inner surface are configured tobe mounted on a header of a core in the aluminum heat exchanger so as toenable welding of the cast tank onto the core.

In another embodiment, the present disclosure relates to a header to beused as part of a core of a heat exchanger, and a method of forming sucha header. The header comprises: a base portion including a plurality ofapertures therein for receiving fluid-carrying tubes of the heatexchanger therethrough; a drafted wall circumferentially surrounding thebase portion and slanted to the plane thereof; and a curved filletlinking the base portion to the drafted wall and providing alignmentsupport during welding of a tank onto the core. The drafted wallprovides an attachment surface for welding the tank onto the core.

In a further embodiment, the present disclosure relates to a core of aheat exchanger. The core comprises: a plurality of fluid-carrying tubes;a plurality of fins interleaved with the plurality of fluid-carryingtubes, wherein a set of fins from the plurality of fins is disposedalong a first pair of opposite sides of the core; and a pair of headers,wherein each header in the pair of headers is disposed over theplurality of fluid-carrying tubes along a corresponding one of a secondpair of opposite sides of the core. Each header is configured asprovided in the preceding paragraph.

In a still further embodiment, the present disclosure relates to analuminum heat exchanger that comprises an aluminum core and a pair ofcast tanks as provided in the preceding paragraphs. The heat exchangerfurther includes a pair of steel sidebrackets for strength and support.A method of obtaining and assembling various parts of the heat exchangeris also contemplated according to one embodiment of the presentdisclosure.

In a still further embodiment, the present disclosure relates to anall-aluminum (or aluminum alloy) industrial heat exchanger (or radiator)that provides consistency in tank-to-header joint locations to allow useof robotic welding of tanks to headers. A header design that includesthe combination of a curved fillet and a drafted wall facilitates easyinsertion of the radiator tank onto the core of the radiator and allowsfor different vertical core growth during baking of the core. The tanksmay be made by casting, so that they do not require machining. The innersurface of the aluminum cast tank is welded onto the header and isconfigured to match in geometry with that of the drafted wall of theheader. Alternately, the tanks may be may be made of plastic and may,for example, be molded.

Each tank may include suitably-shaped indentations (e.g., approximatelysideways T-shaped indentations in an embodiment) to facilitate linkingthe tanks to sidebrackets using sidebracket mounts (or isolators). Forexample, the indentations may be located at the four corners of the casttank, as is illustrated in FIGS. 8A-8D. Attaching the tank to thesidebracket or otherwise to a heat exchanger using the sidebracketmounts permits the tank and the sidebracket, core, or other part of theheat exchanger to which the tank is attached to expand and contract atdifferent rates. In that way, separation of the tank from that to whichit is attached is less likely to result in damage to the assembly. Incertain embodiments, a cast aluminum or molded plastic tank is coupledto a strong, inexpensive steel sidebracket by way of the isolators topermit the materials of the tank and sidebracket to move with respect toone another.

Sidebrackets may be captured by attaching nuts to the threaded insertsof the sidebracket mounts, without requiring any machining, welding orbrazing. The sidebracket mounts or isolators thus allow for flexiblemounting of sidebrackets, to accommodate thermal expansion of the corewithout causing damage to the core.

In a still further embodiment, a heat exchanger assembly includes: atank having at least two indentations; and one or more isolators, eachisolator having a base at least partially disposed in one of theindentations and a coupler extending from the base for coupling the tankto at least one other component of the heat exchanger.

In a still further embodiment, a tank to be used as part of a heatexchanger includes an elongate housing having a substantially U-shapedcross section, wherein the elongate housing includes: a pair of longerside panels, wherein each longer side panel has a first outer surfaceand a first inner surface; a top panel; a pair of shorter side panels,wherein each shorter side panel has a second outer surface and a secondinner surface; and at least two indentations, each indentation in atleast one of said pair of longer side panels, said top panel, and saidpair of shorter side panels.

Other embodiments, which may include one or more parts of theaforementioned method or systems or other parts, are also contemplated,and may thus have a broader or different scope than the aforementionedmethod and systems. Thus, the embodiments in this Summary of theInvention are merely examples, and are not intended to limit or definethe scope of the invention or claims.

BRIEF DESCRIPTION OF THE DRAWINGS

For the present disclosure to be easily understood and readilypracticed, the present disclosure will now be described for purposes ofillustration and not limitation, in connection with the followingfigures, wherein:

FIG. 1 illustrates a perspective view of an aluminum weldment of anexemplary industrial heat exchanger (or radiator) according to oneembodiment of the present disclosure;

FIG. 2 shows another perspective view depicting additional components ofthe heat exchanger according to one embodiment of the presentdisclosure;

FIGS. 3A and 3B depict cross-sectional views of a fully-assembled heatexchanger according to one embodiment of the present disclosure;

FIG. 4 shows component details of the core illustrated in FIGS. 1 and 2;

FIGS. 5A-5C illustrate constructional details of an exemplary set offins according to one embodiment of the present disclosure;

FIGS. 6A and 6B show top and front views, respectively, of the headershown perspectively in FIGS. 1 and 4;

FIG. 7 shows cross-sectional details of a header according to oneembodiment of the present disclosure;

FIG. 8A depicts a top view of an embodiment of a cast tank;

FIGS. 8B-8C depict cross-sectional details of the cast tank of FIG. 8A;

FIG. 8D illustrates an end view of the cast tank of FIGS. 8A-8C;

FIG. 9A depicts a larger top view of the cast tank shown in FIG. 8;

FIG. 9B depicts a front view of the cast tank of FIG. 9A

FIG. 10 shows a close-up view of tank-to-header seam locations in anembodiment where a tank is mounted on a header;

FIGS. 11A and 11B illustrate side and end views, respectively, of anisolator (or a sidebracket mount) according to one embodiment of thepresent disclosure;

FIGS. 12A and 12B depict front and top views, respectively, of asidebracket according to one embodiment of the present disclosure;

FIG. 13A illustrates a front view of an embodiment of a core;

FIG. 13B illustrates an end view of the embodiment of the coreillustrated in FIG. 13A;

FIG. 14A illustrates a front view of another embodiment of a weldment;

FIG. 14B illustrates an end view of the embodiment of the weldmentillustrated in FIG. 14A;

FIG. 15A illustrates a front view of another embodiment of a radiator;and

FIG. 15B illustrates an end view of the embodiment of the radiatorillustrated in FIG. 15A.

DETAILED DESCRIPTION

The accompanying figures and the description that follows set forth thepresent disclosure in embodiments of the present disclosure. However, itis contemplated that persons generally familiar with mechanical designs,and more particularly with designs of industrial heat exchangers, willbe able to apply the teachings of the present disclosure in othercontexts (e.g., for automotive radiators) by modification of certaindetails. Accordingly, the figures and description are not to be taken asrestrictive of the scope of the present disclosure, but are to beunderstood as broad and general teachings. In the discussion herein,when any numerical value is referenced, such value is understood to be apractically-feasible design approximation taking into account variancesthat may be introduced by such mechanical operations as machining,tooling, drilling, casting, etc.

It is observed at the outset that the directional terms such as “top,”“bottom,” “right,” “left,” “horizontal,” “vertical,” “upper,” “lower,”etc., and derivatives thereof are used herein for illustrative purposeonly to facilitate description and understanding of relative positionsof various mechanical components or parts constituting the aluminum heatexchanger according to the teachings of the present disclosure. Hence,such terms and derivatives thereof shall relate to the presentdisclosure as it is oriented in the drawing figures provided herein.

It is further observed here that the mechanical structures, components,assemblies, or engineering drawings thereof illustrated in variousfigures in the instant application are not drawn to scale, but arerather illustrated for the convenience of understanding various designaspects of an aluminum heat exchanger according to the teachings of thepresent disclosure. Additionally, the terms “heat exchanger” and“radiator” are used interchangeably herein to refer to a coolingmechanism used, for example, in an industrial internal combustion (IC)engine. It is noted here that although the discussion below primarilyrefers to industrial heat exchangers for internal combustion engines,various heat exchanger designs discussed herein may be equally used inautomotive applications (e.g., as car radiators) and also withnon-engine coolers such as, for example, hydraulic oil coolers,transmission oil coolers, charge-air coolers, etc., used in variousindustrial applications (e.g., oil coolers used to cool hydraulic oil ina tractor or charge-air coolers used to cool turbo-charged air for aturbo charged internal combustion engine). Also, the term “aluminum” inthe discussion below is used for the sake of convenience only; it may beconstrued to include a pure aluminum material or an aluminum alloymaterial.

FIG. 1 illustrates a perspective view of an aluminum weldment 10 of anexemplary industrial heat exchanger (or radiator) 36 (shown in detail inFIG. 2) according to one embodiment of the present disclosure. Thealuminum weldment 10 may include an aluminum core 11 and two aluminumcast tanks 20, 22. The core 11 may comprise a plurality offluid-carrying (e.g., radiator coolant-carrying) tubes 12 interleavedwith a plurality of elongate fins 14. A pair of side plates 15, 16 alsomay be mounted on the outermost fins 14 along two opposite sides of thecore 11 as shown in FIG. 1 for additional strength and support to thecore 11. The core 11 may further include a pair of headers 18, 19disposed over fluid-carrying tubes 12 along two other opposite sides ofthe core 11 as also shown in FIG. 1. The members of the core 11—i.e.,the two headers 18-19, the tubes 12, the fins 14, and the side plates15-16—may be made of aluminum or aluminum alloy materials and brazed toeach other during a baking process. Fins may be brazed to tubes, andtubes may be brazed to headers during the brazing process as is known inthe art. A more detailed view of various components of the core 11 isprovided in FIG. 4, which is discussed later below. Each of the casttanks 20, 22 is in the form of an elongate aluminum housing 20, 22having a substantially U-shaped cross section (not shown in FIG. 1, butillustrated in more detail in FIGS. 8 and 9). For the ease ofdiscussion, the same reference numerals (“20” and “22”) are used tointerchangeably refer to the cast tank and aluminum housing forming thecast tank.

Each cast tank 20, 22 may be made of aluminum or aluminum alloymaterial. Because tanks 20, 22 are cast around an inner core, the raw(not machined) inside surfaces will have a tighter dimensional toleranceand, hence, a tank 20, 22 will be more easily welded to the core 11using this surface than either the raw outside or raw bottom surfaces.Each aluminum housing 20, 22 further includes a top panel 21A and a side21B-21D that may include a pair of longer side panels 21B and a pair ofshorter side panels 21C-21D, the side 21B-21D terminating at a rim 23.For ease of illustration, the top panel 21A, one longer side panel 21B,and two shorter side panels 21C-21D of the cast tank 20 are identifiedin FIG. 1. However, although similar identifications are not providedfor the cast tank 22 in FIG. 1 for the sake of simplicity, theseconstructional details may be evident from the illustration in FIG. 1.Each cast tank 20, 22 may further include one or more indentations.

For example, in an embodiment, each cast tank 20, 22 may include asuitably-shaped indentation at each end of the top panel (at thejuncture of the pair of longer side panels 21B and shorter side panels21C-21D). In the embodiment of FIG. 1, the cast tanks 20, 22 are shownwith approximately sideways (as illustrated in FIGS. 1-3, 8, and 9)T-shaped indentations. Some of these indentations are identified in FIG.1 by reference numerals 32A-32F. Additional cross sectional details of acast tank (e.g., the cast tank 20) with these indentations are providedin FIGS. 8 and 9 and discussed below. These indentations permit simplemounting of sidebrackets of any suitable metal (e.g., steel sidebrackets42 and 44 in FIG. 2) onto the weldment 10 without the need for secondarymachining, welding or brazing, while allowing for thermal expansion ofthe core 11 and the cast tanks without causing damage to the core, asdiscussed below.

Each indentation (e.g., one or more of 32A-32F) may be located otherwiseas desired. For example, one or more indentations may be located in thetop panel (e.g., 21A), one or both longer side panels (e.g., one or bothof 21B), or one or both shorter side panels (e.g., one or both of21C-21D). In various embodiments, one or more indentations may belocated in at least one of the pair of longer side panels, the toppanel, and the pair of shorter side panels, and thus in any combinationof that top panel, one or both longer side panels, and one or bothshorter side panels. For example, in one such embodiment, one or moreindentations may be formed in the top panel. In another embodiment, oneor more indentations may be formed in a top panel and further in one orboth a longer side panel and shorter side panel. For example, asdescribed herein, each of four indentations may be formed at a differentone of the four corners of the top panel, and thus at the juncture ofthe top panel, a longer side panel, and a shorter side panel.

In the embodiment of FIG. 1, each cast tank 20, 22 further includes apair of holes 24A-24B and 25A-25B, respectively, formed in aspaced-apart manner on one of the longer side panels 21B. These holespermit welding or other attachment of connections apparatuses andconnection plugs to the respective cast tank 20, 22. For example,connection 26A and connection plug 27A may be welded to the cast tank20, whereas connection 26B and connection plug 27B may be welded to thecast tank 22 via respective holes as shown in FIG. 1. The connections26A-26B may function as fluid inlet and outlet ports for entry and exitof radiator coolant into and out of the radiator 36 during operation ofthe heat exchanger 36. One of the cast tanks (e.g., the cast tank 20 inFIG. 1) may also include an inlet hole 28 formed on its top panel 21A toreceive a fillneck 30 to be welded to the cast tank 20 for externalfluid input and to receive a pressure regulating cap (not shown). Theholes 24A-24B and 25A-25B also allow attachment of additional radiatorcomponents (not shown in FIG. 1, but shown in FIG. 2) such as a petcock38, a fillneck connection 40, and an NPT (national pipe thread) plug 39for an LCI (low coolant indicator) to the respective cast tank 20, 22.Radiator bottom mounts 34A-34B may be attached to the bottom cast tank22 as illustrated in FIG. 1 to provide for mounting.

In one embodiment, all the holes (24A-24B, 25A-25B, and 28) and allindentations (e.g., T-shaped indentations 32A-32F) are cast into thealuminum housing of their respective cast tank 20, 22 along with thehousing structure (including its top panel 21A, longer side panels 21B,and shorter side panels 21C-21D) so as to form a unitary structure forthe cast tank 20, 22 as can be seen from various figures herein,including FIGS. 1-3, 8, and 9. The holes in the aluminum housing may beformed by casting tubes into the tank. After connections 26A and 26B andconnection plugs 27A and 27B are welded to respective cast tanks 20, 22,each cast tank 20, 22 may be welded to the core 11 to assemble theweldment 10. The internal surface (not shown in FIG. 1, but illustratedin FIG. 8) of each cast tank 20, 22 is mounted on and welded to therespective adjacent header 18, 19 of the core 11 without requiring thecast tank 20, 22 to be machined prior to the welding. Once the weldingis complete, petcock 38, plug 39 and fillneck connection 40 may bescrewed into the weldment 10.

FIG. 2 shows another perspective view depicting additional components ofthe heat exchanger 36 according to one embodiment of the presentdisclosure. The discussion of weldment 10 and its parts shown in FIG. 1is not repeated herein for the sake of brevity. Although petcock 38, NPTplug 39 for LCI, and fillneck connection 40 were not shown in FIG. 1,they have been previously discussed in conjunction with discussion ofthe weldment 10 in FIG. 1. Hence, only the sidebrackets 42, 44 and theirmounting mechanism will be discussed herein with reference to FIG. 2. Asmentioned earlier, the indentations (32A-32C, etc.) in the cast tanks20, 22 permit simple mounting of sidebrackets 42, 44 (of any suitablemetal) onto the weldment 10 without the need for secondary machining,welding or brazing. The sidebrackets 42, 44 may be made of steel,because steel sidebrackets 42, 44 provide strength and cost advantagesthat may not be available with aluminum sidebrackets 42, 44. However, incurrent radiator designs, usage of steel sidebrackets 42, 44 on analuminum core would require secondary machining operations, for example,to add threaded holes to tanks 20, 22. On the other hand, if weaker (andgenerally more expensive) aluminum sidebrackets are selected, thenadditional welding or brazing operations may be needed, for example, toassure secure attachment of these aluminum sidebrackets 42, 44 to thecore. Furthermore, heat exchanger designs should provide a method toallow for different amounts of thermal expansion between the core andthe sidebrackets. The sidebracket mounts (discussed below) allow for athermal expansion of a core.

In one embodiment of the present disclosure, the need to adequatelyaccommodate for thermal expansion of the core 11 and the need topreferably avoid secondary machining or welding/brazing operations maybe satisfied by using a flexible sidebracket mounting mechanism thatincludes a plurality of sidebracket mounts or isolators, some of whichare identified as parts 46A-46G in FIG. 2. As shown in FIG. 2, eachelongate sidebracket 42, 44 (e.g., of steel) is mounted over acorresponding side plate 15 or 16 along a corresponding one of twoopposite sides of the core 11. Each sidebracket mount or isolator (e.g.,isolators 46A-46G) may comprise a base 90 that may be a substantiallyI-shaped material formed, such as by molding, around a coupler 92, whichmay be a threaded rod inserted into the base 90, an unthreaded rod thataccepts, for example, a cotter pin, or any other coupler or couplingmechanism desired. Details of an exemplary sidebracket mount accordingto one embodiment of the present disclosure are shown in FIG. 11, whichis discussed below. The I-shaped material may be any of the differenttypes of flexible materials including, for example, a metal, plastic orelastomer. Each sidebracket mount 46A-46G fits into a correspondingindentation (e.g., 32A-32E) in the respective cast tank 20, 22 asdepicted in FIG. 2. Each sidebracket 42, 44 may have a hole (some ofwhich are identified as holes 48A-48G in FIG. 2) in each corner of thesidebracket 42, 44 through which the coupler 92 (as illustrated in FIG.11A) of the respective isolator 46A-46G may appear for mounting thesidebracket 42, 44 over a corresponding side plate 15, 16. Fasteners,such as nuts (e.g., the nuts 50A-50G identified in FIG. 2), may attachto the coupler 92 appearing through the holes in the sidebrackets 42,44, thereby securely linking the sidebrackets 42, 44 to the tanks 20, 22and, hence, mounting them over the respective side plates 15, 16 of thecore 11.

The sidebracket mounts (e.g., mounts 46A-46G shown in FIG. 2) thuspermit the use of (stronger and less expensive) steel sidebrackets 42,44, shroud and core guard (not shown) without the need to resort tosecondary machining or welding/brazing operations because thesidebracket mounts (e.g., mounts 46A-46G shown in FIG. 2) provide amethod of attachment and avoid the extensive contact between twodissimilar metals—the steel of sidebrackets 42, 44 versus the aluminumof the core 11. In one embodiment, the sidebracket mounts (e.g., mounts46A-46G shown in FIG. 2) may provide vibration damping and isolation,and allow for core 11 to expand by a different amount than sidebrackets42, 44.

It is reiterated here that the simplified depiction of the heatexchanger 36 and its parts in FIGS. 1-2 (and elsewhere in the presentapplication) is for illustrative purpose only. It is further notedbecause of their lack of relevance to the present discussion and theavailability of many known configurations, all constructional details ofheat exchangers and radiators are not shown herein for ease ofillustration.

FIGS. 3A and 3B depict cross-sectional views of a fully-assembled heatexchanger (e.g., the heat exchanger 36 shown in FIG. 2) according to oneembodiment of the present disclosure. Some parts are identified in FIGS.3A-3B for ease of reference. However, for the sake of clarity andbrevity, all parts discussed hereinbefore are not labeled in FIGS.3A-3B, nor is the earlier discussion of those parts repeated herein.FIGS. 3A and 3B show in detail how cast tanks 20, 22 are engaged withtheir respective headers 18, 19. The tank-to-header seam locations aredesignated by circles identified by reference numerals 58A through 58Din FIGS. 3A-3B. The substantially U-shaped configuration of a casttank's aluminum housing is also visible in the cross sections of FIGS.3A-3B. It is seen from FIGS. 3A-3B that the slanted inner surface (shownin more detail as exemplary surfaces 76A-76B in FIGS. 8B-8C) at the openend of a cast tank 20, 22 consistently mounts onto an outwardly slanteddrafted wall of a header 18, 19 (shown in more detail as wall 72 in FIG.7 and discussed below) to provide a header-tank welding location thatminimizes part-to-part variations and aids in the use of a roboticwelder for mass welding of header-tank pairs.

FIG. 4 shows component details of the core 11 illustrated in FIGS. 1 and2. These component details are shown to more clearly depict the headers18, 19 according to one embodiment of the present disclosure. Asmentioned before, the aluminum core 11 may include a pair of aluminumheaders 18, 19, a plurality of fluid-carrying aluminum tubes 12interleaved with a plurality of aluminum fins 14, and a pair of aluminumside plates 15, 16. As shown in FIG. 4, in one embodiment, thefluid-carrying tubes 12 may be organized in a plurality of groups,wherein each group may include an identical number of tubes (e.g., threetubes per group as shown in FIG. 4). These groups of tubes may beinterleaved with the fins 14 such that a set of fins may be disposedexternally along a first pair of opposite sides of the core 11 asillustrated in FIG. 4. The fins 14 may carry heat from the tubes 12 andtransfer that heat to air flowing through the fins and around the tubes12 so as to enable transfer of heat from the heated coolant (flowing inthe tubes 12) to the ambient atmosphere. A pair of side plates 15, 16may be disposed over ends of the set of fins 14. The headers 18, 19 maybe mounted on a second pair of opposite sides of the core 11 as shown inFIG. 4. Each header 18, 19 may include a plurality of apertures (oropenings) 60, 62, respectively, for receiving the fluid-carrying tubestherethrough. The tubes 12 may then be brazed or otherwise attached tothe headers 18, 19 as part of core 11 formation, also known as “bakingthe core 11.” Additional constructional details of the headers 18, 19are discussed below with reference to FIGS. 6 and 7. As also mentionedbefore, all the components of the core 11 shown in FIG. 4 may be brazedto each other during a baking process to form a unitary structure forthe core 11 as illustrated in the cross-section of FIG. 3B.

Before addressing details of the header 18, 19 design according to oneembodiment of the present disclosure, FIGS. 5A-5C are discussed hereinto provide additional details of an exemplary elongate fin (or set offins) 14. FIG. 5C depicts a side view of elongate fin 14. FIG. 5Adepicts a front view of elongate fin 14. FIG. 5B is a cross-sectionalview taken along the lines A-A in FIG. 5A. The elongate fin is comprisedof a plurality of individual fins forming zigzag pattern as shown inFIG. 5C. The fins extend between the opposite sides of core 11. Louvers64 consist of sections of elongate fin 14 being cut and bent. Thelouvers 64 redirect the atmospheric air and serve to increase the heattransfer rate as is known in the art. It is noted here that although thereference numeral “14” refers to a set of fins, in the discussionherein, a single reference numeral “14” is used to interchangeably referto such terms as “fin,” “fins,” “set of fins,” “elongate fin,” etc., forease of discussion. The usage of the reference numeral “14” throughoutthe discussion herein to refer to “fins” (either singly or collectively)may be evident from the relevant context.

FIGS. 6A and 6B show top and front views, respectively, of a header(e.g., the header 18) shown perspectively in FIGS. 1 and 4. Each header18, 19 in this embodiment is identical in construction and, hence, onlyone header 18 is shown in FIGS. 6A-6B. The apertures 60 and the overallcontour of the header 18 are clearly visible in FIG. 6A. In oneembodiment, the width (“HW”) of the header 18 is approximately 76 mm(3.00 inches), the length (“HL”) of the header 18 is approximately 449mm (17.7 inches), and the peripheral height (“HH”) of the header 18 isapproximately 10 mm (0.4 inches). Additional constructional details ofthe header 18 are shown in the cross-section view in FIG. 7 taken alongthe lines A-A in FIG. 6A.

As mentioned above, FIG. 7 shows cross-sectional details of the header18 according to one embodiment of the present disclosure. The header 18may be made of aluminum or aluminum alloy suitable for allowing brazingof the header 18 to the fluid-carrying tubes 12 and also for allowingthe header 18 to be welded to the aluminum cast tank 20. In oneembodiment, the header 18 is formed by stamping. The header 18 mayinclude a substantially planar base portion 68 that comprises theplurality of apertures 60 for receiving the fluid-carrying tubes 12therethrough. The header 18 may further include a curved fillet 70 and adrafted wall 72. The drafted wall 72 may circumferentially surround thebase portion 68 and may be slightly outwardly slanted (instead of beingperpendicular) to the plane of the base portion 68 as can be seen inFIG. 7. Thus, opposing sides of the drafted wall 72 (e.g., as shown inFIG. 7) are progressively farther apart as they extend from the curvedfillet 70. In other words, the drafted wall 72 is formed in thedirection of the core 11 (of which the header 18 is a part) and providesan attachment surface for welding the tank 20 onto the header 18 asdiscussed in more detail later below. The curved fillet 70 functions tolink the base portion 68 to the drafted wall 72 and provides alignmentsupport to the tank 20 during welding of the tank 20 onto the header 18.The curvature of the curved fillet 70 may be configured to accommodatethe slightly slanted orientation of the drafted wall 72 (respective tothe plane of the base portion 68) so as to provide a unitary structurefor the header 18 having a cross-sectional continuity from the innerbase portion 68 to the outer drafted wall 72. Regarding the extent ofcurvature of the curved fillet 70, it is seen from FIGS. 7 and 3A that,in one embodiment, the curvature of the curved fillet 70 may be suchthat the plane tangential to the top of the curved fillet 70 is parallelto and higher than the plane containing the top surfaces of theapertures 60, but lower than the plane tangential to the tops of thefluid-carrying tubes 12 when those tubes 12 are received by the baseportion 68.

In the embodiment of FIG. 7, the combination of the drafted wall 72 andthe curved fillet 70 results in maintaining a consistent tank-to-headerseam location (discussed further with reference to FIGS. 8 and 9 below)for fitting and during welding of the tank 20 onto the core 11 despiteoccurrence of different amounts of core growth during baking of the core11 (i.e., during brazing of different parts of the core 11). Thus, theheader design enables easy insertion of the tanks onto the core in amanner that permits the tanks to maintain a consistent spacing whenmounted on the headers despite different amounts of core growth thatoccur during the baking of the core. This consistency in the location oftank-to-header joints permits the use of a robotic welder so that bothsuperior quality and reduced costs result.

It is noted here that the terms “base portion,” “curved fillet,” and“drafted wall” are used herein for the sake of convenience only toillustrate and discuss structural details of the header 18. These termsdo not imply piecemeal construction of the header 18 or that the header18 is composed of disjointed parts. The entire header 18 may be formedin such a manner as to result in a unitary, homogenous structure thathas cross-sectional continuity throughout its metallic composition. Inother words, the header 18 is not necessarily formed by forming each“part” 68, 70, 72 individually and then “joining” these parts to arriveat the final header structure. Rather, the header 18 may be a unitary,homogenous structure, having all of its “parts” formed simultaneously.

FIGS. 8A-8D and FIGS. 9A-9B depict cross-sectional details of a casttank (e.g., the cast tank 20) according to one embodiment of the presentdisclosure. It is noted here that although all components in thecross-sectional views in FIGS. 8A-8D and FIGS. 9A-9B are not identifiedfor the sake of simplicity, these components can be easily recognizedwhen these cross-sectional views are compared against the perspectiveviews in FIGS. 1 and 2. In the top view of FIG. 8A, the approximatelyT-shaped indentations 32A-32B and 32D-32E at the corners of the casttank 20 (i.e., at the juncture of the longer and shorter side panels ofthe cast tank) are identified along with the inlet hole 28 and sideholes 24A-24B. The top view in FIG. 9A is substantially similar to thatin FIG. 8A and, hence, additional details are not provided in FIG. 9A.The sideways (as depicted in FIG. 9B) T-shape of the corner indentations32A-32B and 32D-32E in the cast tank housing 20 is more clearly visiblein the front view of FIG. 9B along with the side holes 24A-24B. As notedbefore, the indentations (e.g., 32A-32B and 32D-32E for tank 20) in thecast tanks allow flexible linking of the weldment 10 to the steelsidebrackets 42, 44 (FIG. 2) for providing strength and support to theheat exchanger 36 (FIG. 2) and for accommodating thermal expansion ofthe core 11 without causing damage to the core 11. The substantialU-shape of the aluminum housing of the cast tank 20 is visible in thefront views of FIG. 8B (taken along the sectional lines A-A in FIG. 8A)and 9B, and in the side view of FIG. 8C (taken along the sectional linesB-B in FIG. 8A). With reference to FIGS. 9A-9B, in one embodiment, thewidth (“TW”) of the cast tank 20 is approximately 84 mm (3.3 inches),the length (“TL”) of the cast tank 20 is approximately 457 mm (18inches), and the peripheral height (“TH”) of the cast tank 20 isapproximately 60 mm (2.4 inches).

Referring back to FIG. 8A (and in conjunction with FIG. 1), it isobserved that the top panel 21A, two longer side panels 21B and 21E, andtwo shorter side panels 21C-21D are also identified in FIG. 8A. It isnoted here that the side panel 21E was not visible in FIG. 1 and, hence,was not identified therein. Each of the side panels may be considered tohave an outer surface and an inner surface, wherein the outer and innersurfaces of each shorter side panel are identified by references “75A”and “76A,” respectively, in FIG. 8B, and the outer and inner surfaces ofeach longer side panel are identified by references “75B” and “76B,”respectively, in FIG. 8C. It is noted that, in the embodiment of FIGS.8B-8C, each inner surface 76A-76B of the tank 20 may be slightlyoutwardly slanted (instead of being perpendicular) to the plane of thetop panel 21A so as to facilitate insertion of the tank 20 onto the core11. Thus, opposing inner surfaces 76A (on opposing shorter side panels21C and 21D) and opposing inner surfaces 76B (on opposing longer sidepanels 21B and 21E) are, correspondingly, progressively farther apart asthey extend from the top panel 21A. This outward slant coupled with aslight taper in the thickness of the tank's side panels allows theinternal surfaces 76A-76B of the cast tank 20 to be mounted on thecorresponding slanted attachment surface of the drafted wall 72 in theheader 18 in such a manner as to provide a consistent tank-to-headerseam location as indicated by references 58A through 58D in FIGS. 3A-3B.In other words, when the cast tank 20 is mounted on its correspondingheader 18, the inner surfaces 76A-76B of the cast tank 20 mateconsistently and well with the drafted wall 72 of the header so as toprovide for a welding location that can facilitate robotic welding ofeach such tank-header pair.

As in the case of the header in FIG. 7, the terms such as “longer sidepanel,” “shorter side panel,” and “top panel” are used in conjunctionwith the cast tank in FIGS. 8-9 merely for the sake of convenience andto facilitate discussion. These terms do not imply that the cast tanks20, 22 are fabricated using disparate or disjointed “parts” orseparately manufactured “panels,” which are later joined in a piecemealmanner to form the cast tanks 20, 22. Rather, like headers, the casttanks 20, 22 according to the teachings of the present disclosure may beformed in such a manner as to result in a unitary, homogenous structurewhose metallic composition has cross-sectional continuity. In otherwords, all of the cast tank “panels” (and their corresponding inner andouter surfaces) may be formed simultaneously during the tank castingoperation. Thus, for example, the references “76A” and “76B” essentiallyrefer to a single peripheral (continuous) “inner side surface” of thecast tank 20, the references “75A” and “75B” refer to a singleperipheral (continuous) “outer side surface” of the cast tank 20, and soon for other similar structures in the cast tank 20.

FIG. 10 shows a close-up view of the tank-to-header seam locations whena tank (e.g., the tank 20 in FIG. 1) is mounted on a header (e.g., theheader 18 in FIG. 1) according to one embodiment of the presentdisclosure. FIG. 10 provides a magnified view of the seam locations58A-58B, which also have been identified earlier in FIGS. 3A-3B.Although FIG. 10 focuses on the tank 20, it is evident that the othertank 22 may be mounted in a similar manner. Hence, the discussion hereinapplies to all tank-header joints in a heat exchanger according to thepresent disclosure. As noted before, the tank attachment surfaceprovided by the drafted wall 72 of the header 18 enables easy insertionof the tank 20 onto the header 18 in a manner that permits the tank 20to maintain a consistent spacing when mounted on the header 18, in spiteof the different amounts of vertical core growth that occur during thebaking of the core 11 (containing the header 18). The tank 22 may be ofaluminum (or aluminum alloy—e.g., the aluminum alloy 356 known in theart as “Alloy 356” or “Aluminum 356”) and may be formed by casting so asto avoid the need for machining the tank prior to welding and to alsoprovide for tighter tolerances suitable for robotic welding. Forexample, a cast tank 22 may have more consistent dimensions than a tankotherwise formed, for example of sheet metal, and those consistentdimensions allow the tank 22 to be placed in consistent relation to theheader 18 and/or the core 11, thus permitting a consistently repetitiverobotic welder to be used to attach the cast tank 22 to the core 11.Because an aluminum casting tends to cool more consistently around itsinner core, the distances between the inside walls (i.e., the internalsurfaces 76A-76B) of the casting (i.e., cast tank 20) have the smallestpart-to-part variations. This consistency in the tank design, whencoupled with the matching geometry of the drafted wall 72 of the header18, results in a consistent tank-to-header seam location for eachtank-header pair. This not only allows interchangeable tank-header pairs(e.g., tank 20 can be used along with header 19, or with any othersimilar header) because of very minimal part-to-part variations, but theconsistent location of tank-header joints also permits the use of arobotic welder to weld such tank-header pairs, thereby resulting insuperior quality and reduced costs.

It is observed here that, during robotic welding, the cast tanks 20, 22may be held in place (in a spaced-apart manner) by gripping the tanks20, 22 through their indentations 32A-32F. The core 11 may be theninserted in the spacing between the tanks 20, 22 and the tanks 20, 22may be suitably moved to snugly fit onto their corresponding headers 18,19. After tanks 20, 22 are securely mounted over corresponding headers18, 19, a robotic welding arm may be brought in to weld the tank's sidepanels (e.g., the longer side panels 21B, 21E, etc.) onto the header 18,19 wall. The tanks 20, 22 may be mounted over the headers 18, 19 so asto provide consistency in tank-to-header seam locations and facilitateexpeditious and economical robotic welding.

Furthermore, as mentioned before, the cast tank 20 may not require anymachining prior to its welding onto the header 18. The lack of machiningmay result in improved material flow path and decreased cost because ofthe simpler three-step (cast-weld-assemble) process discussed herein. Onthe other hand, in traditional cast tank designs, additional machiningmay be needed to create a flat bottom tank surface to facilitate weldingof the tank onto the header and to provide a method for sidebracketattachment. Although the machining may succeed in creating a flatsurface, it may fail in creating an interchangeable tank design that hasa consistent tank-to-header seam location whenever such a tank ismounted on a header and such machining requires additional time andeffort to perform. The cast tanks 20, 22 according to the teachings ofthe present disclosure may provide interchangeable tank designs withoutthe need for any machining. Such cast tanks 20, 22 may be well suitedfor medium production levels of at least 2000 units per year forindustrial heat exchangers.

FIGS. 11A and 11B illustrate details of an isolator (or a sidebracketmount) 88 according to one embodiment of the present disclosure.Isolators 88 may be used to couple one or more tanks 20, 22 to one ormore components of the heat exchanger, such as one or more sidebrackets42, 44. The isolator 88 may represent any of the isolators 46A-46G shownin FIG. 2. Hence, the discussion of the isolator 88 equally applies toall the isolators (visible or not visible in FIG. 2) that may be used inthe heat exchanger 36 according to the teachings of the presentdisclosure. The isolator 88 may include a flexible I-shaped material 90molded around a threaded insert 92, and may be used to connect the heatexchanger tanks 20, 22 to the sidebrackets 42, 44 as illustrated in FIG.2. The I-shaped material may be a metal, a plastic (such as Nylon 6/6),or an elastomer (such as EPDM (ethylene propylene diene monomer) orversatile thermoplastic vultanizate (for example, the vulcanizatemarketed by Exxon Mobil® as Santoprene™ 101-64)). The threaded insert 92may be a metallic bolt (e.g., a steel bolt) or a bolt made of harderplastic, for example. The sidebracket mount 88 fits into a correspondingT-shaped indentation (i.e., indentations 32A, 32B, 32D, and 32Eillustrated in FIGS. 8A-8D, 9A, and 9B) in a cast tank 20, 22 so as toallow a nut (e.g., any of the nuts 50A-50G shown in FIG. 2) to beattached to the threaded insert 92 (which may appear via a correspondinghole (e.g., any of the holes 48A-48G) in the sidebracket 42, 44 as shownin FIG. 2) to attach the sidebracket 42, 44 to the cast tank 20, 22.This isolator-based sidebracket joint enables the use of stronger (andless expensive) steel sidebrackets 42, 44 without requiring additionalmachining, welding, or brazing operations, and without having twodissimilar metals (steel of the sidebracket 42, 44 and aluminum of thecast tank 20, 22 and its weldment 10) contact with each other.Furthermore, the flexible sidebracket mount 88 allows for thermalexpansion of the core (e.g., the core 11 in FIG. 2) and providesvibration isolation and damping during operating conditions.

From the front view in FIG. 11A, it is noted that, in one embodiment,the height (“IH”) of the isolator 88 is approximately 28 mm (1.1inches), the length or width (“IW”) of the isolator 88 (including thethreaded portion 92) is approximately 36 mm (1.4 inches). From the sideview in FIG. 11B, it is noted that the depth or thickness (“ID”) of theI-shaped material 90 is approximately 20 mm (0.8 inch).

It is noted here that the foregoing discussion provides details of anexemplary embodiment in which the substantially I-shaped isolators 88may suitably fit in the corresponding approximately T-shapedindentations (e.g., indentations 32A, 32B, 32C, etc. shown in FIG. 2) ina cast tank 20, 22. However, in an alternative embodiment, cast tanks20, 22 may have indentations of a different shape (e.g., indentationsthat are substantially I-shaped, L-shaped, etc.), and the correspondingisolators (or sidebracket mounts) may be suitably configured to fit intothese indentations. For example, in certain embodiments, isolators maybe substantially U-shaped to fit into substantially L-shapedindentations.

In various embodiments, the heat exchanger (e.g., the heat exchanger 36)may include one or more isolators. In those embodiments, each isolatormay be shaped to be at least partially disposed in one or moreindentations, such as one isolator engaging two or more indentations.For example, the isolator may be shaped with two protrusions that eachfit into a different of two indentations

a tank having at least two indentations; and one or more isolatorsengaging the at least two indentations, each isolator having a base atleast partially disposed in one of the indentations and a couplerextending from the base for coupling the tank to at least one othercomponent of the heat exchanger.

Such isolators may be constructed in a manner similar to theconstruction of the substantially I-shaped isolators discussedhereinabove. Hence, additional details of different configurations ofindentations and corresponding matching isolators are not providedherein for the sake of brevity.

FIGS. 12A and 12B depict front and top views of a sidebracket (e.g., thesidebracket 42) according to one embodiment of the present disclosure.The corner holes 48B-48E of the sidebracket 42 are visible in FIG. 12B.As noted before, the sidebracket 42 may be made of steel to impartstrength to the heat exchanger 36 (shown in FIG. 2). In one embodiment,the length (“SL”) of the sidebracket 42 is approximately 480 mm (18.9inches), the height or depth (“SH”) of the sidebracket 42 isapproximately 30 mm (1.2 inches), and the width (“SW”) of thesidebracket 42 is approximately 91 mm (3.6 inches). Additionalconstructional details of the sidebracket 42 are not relevant to thepresent discussion and, hence, are not provided herein.

FIGS. 13-15 illustrate various dimensional details for variouscomponents of the heat exchanger 36 shown in FIG. 2 according to oneembodiment of the present disclosure. For the sake of simplicity and toavoid repetition, all the parts in FIGS. 13-15 are not identified inview of their detailed identifications in FIGS. 1-12 discussedhereinbefore.

FIG. 13A shows a front view and FIG. 13B shows a side view of thefully-assembled core 11 (whose components are depicted in FIG. 4). Withrespect to FIGS. 13A-13B, in one embodiment, the length (“CL”) of thecore 11 (including side panels 15-16) is 457 mm (18 inches), the height(“CH”) of the core 11 (measured as the distance between the tops offluid-carrying tubes 12) is 395 mm (15.6 inches), and the width or depth(“CW”) of the core 11 (which may be the same or close to the same as thewidth of the headers 18-19) is 76 mm (3 inches).

FIG. 14A shows a front view and FIG. 14B shows a side view of theassembled weldment 10 (whose unassembled view is provided in FIG. 1).With respect to FIGS. 14A-14B, in one embodiment, the length (“WL”) ofthe weldment 10 (which length may be the same as the length of each casttank 20, 22) is approximately 457 mm (18 inches), the height (“WH”) ofthe weldment 10 (measured as the distance between the top of thefillneck 30 and the bottom of the mount 34A or 34B) is approximately 550mm (21.7 inches), and the width or depth (“WD”) of the weldment 10(measured as the distance between the top of the connector 26A or 26Band the distant, opposite end of a shorter side panel of the respectivecast tank 20 or 22) is approximately 121 mm (4.8 inches).

FIG. 15A shows a front view and FIG. 15B shows a side view of theassembled heat exchanger 36 (whose unassembled view is provided in FIG.2). With respect to FIGS. 15A-15B, in one embodiment, the length (“EL”)of the heat exchanger 36 (measured as an end-to-end distance between thesidebracket nuts 50G and 50B or 50F and 50D) is approximately 488 mm(19.2 inches), the height (“EH”) of the heat exchanger 36 (which heightis the same as the height of the weldment 10 in FIG. 14A) isapproximately 550 mm (21.7 inches), and the width or depth (“EW”) of theheat exchanger 36 (measured as the distance between the top of theconnector 26A or 26B and the opposite, distant end of the respectivesidebracket 42 or 44) is approximately 124 mm (4.9 inches).

Another embodiment is a method of attaching a header to a tank. Asdescribed herein, the tank may be cast, such as out of aluminum, ormolded, such as out of plastic. This embodiment is discussed below withrespect to header 18 and tank 20, though the method may similarly applyto header 19 and tank 22. Referring to FIGS. 1 and 10, the methodincludes forming the tank 20 with a top panel 21A and a side 21B-21Ehaving an inner surface 76A-76B, the side 21B-21E extending from the toppanel 21A and terminating in a rim 23 such that a dimension from the toppanel 21A to the rim 23 is consistent and a dimension along the rim 23is consistent. The dimension from the top panel 21A to (any part of) therim 23 may be the distance, from the perspective of FIG. 10, from apoint on the top panel 21A to the rim 23 in the direction perpendicularto an imaginary line connecting the rim 23 between opposing side panels(e.g. 21C and 21D, or 21B and 21E as shown in FIG. 8A) of the tank 20.That dimension may be consistent, and thus approximately the same alongthe entire rim 23.

The dimension along the rim 23, as introduced above, may be a consistentdistance between opposing sides (i.e., distance between longer sidepanels 21B and 21E, and distance between shorter side panels 21C and21D).

In an embodiment, the aforementioned consistent dimensions (i.e.dimension from the top panel 21A to the rim 23 and the dimension alongthe rim 23) and location of the rim 23 are maintained within a tighttolerance that may not be achievable using sheet goods.

The header 18 may be formed with a base portion 68 and a drafted wall 72extending from the base portion 68. The header 18 may be moved or slidwithin the tank 20 such that the drafted wall 72 moves adjacent to orslides along the inner surface 76A-76B of the side 21B-21E of the tank20. Because of the outwardly slanted inner surface 76A-76B of the side21B-21E of the tank 20 and outwardly slanted outer surface of thedrafted wall 72 of the header 18, the drafted wall 72 may, in anembodiment, remain in contact or nearly in contact with the innersurface 76B near the rim 23 as the drafted wall 72 moves or slideswithin the tank 20. Thus, at different of those moved distances, theheader 18 may still be welded to the tank 20 along the rim 23. Thisenables a fixed distance between each tank-to-header joint to bemaintained. This fixed distance facilitates robotic welding, since therobotic welder can be programmed to automatically weld the header 18 andtank 20 together along the consistent, and thus known, dimension.

In an embodiment, the drafted wall 72 of the header 18 remains incontact or nearly in contact with inner surface 76A-76B of the side21B-21E of the tank 20 near the rim 23 as the drafted wall 72 slideswithin the tank 20 because, at least in part, the outer surface of thedrafted wall 72 is outwardly slanted. In another embodiment, the draftedwall 72 of the header 18 remains in contact or nearly in contact withthe inner surface 76A-76B of the side 21B-21E of the tank 20 near therim 23 as the drafted wall 72 slides within the tank 20 because, atleast in part, both the outer surface of the drafted wall 72 and theinner surface 76A-76B of the side 21B-21D of the tank 20 are outwardlyslanted.

In an embodiment, the drafted wall 72 is adjacent to or slides along theinner surface 76B of the side 21B-21D of the tank 20. Thus, a gap mayexist between the drafted wall 72 and the tank 20 having a width notmore than could be filled by a welding bead, or the drafted wall 72 maycontact the tank 20 or slide along the inner surface 76B of the side21B-21D of the tank 20. For example, in one embodiment, the drafted wall72 may slide along the inner surface 76B of the side 21B-21D of the tank20, thus overlapping the tank 20 up to one inch.

The foregoing embodiments describe an aluminum (or aluminum alloy)industrial heat exchanger (or radiator) that provides consistency intank-to-header joint locations to allow use of robotic welding of tanksto headers. A header design that includes the combination of a curvedfillet and a drafted wall facilitates easy insertion of the radiatortank onto the core of the radiator and allows for a degree ofunpredictable core growth during baking of the core. The tanks are madeby casting in such a manner that machining is not required. The innersurface of the aluminum cast tank is welded onto the header and isconfigured to match the geometry of the drafted wall of the header. Eachcast tank of the radiator includes suitably-shaped indentations (e.g.,approximately sideways T-shaped indentations) at the four corners of thecast tank to facilitate linking of the cast tanks to (frequentlystronger and less expensive) steel sidebrackets using sidebracket mounts(or isolators) that may be made of a flexible material molded around athreaded insert. Sidebrackets may furthermore be captured by attachingnuts to the threaded inserts of the sidebracket mounts, withoutrequiring any machining or welding/brazing operations. The sidebracketmounts or isolators thus allow for flexible mounting of sidebrackets,and allow for thermal expansion of the core. As mentioned before,various dimensional details provided herein are exemplary in nature, andcan be modified as needed without departing from the scope of theteachings in the present disclosure. Also, although certain discussionherein focuses on an industrial heat exchanger for internal combustionengines, the radiator design principles discussed herein may be used todesign similar heat exchangers for use in other applications, including,for example, heat exchangers used in automotives, refrigeration,hydraulic oil coolers, etc.

While the disclosure has been described in detail and with reference tospecific embodiments thereof, it will be apparent to one skilled in theart that various changes and modifications can be made therein withoutdeparting from the spirit and scope of the embodiments. Thus, it isintended that the present disclosure cover the modifications andvariations of this disclosure provided they come within the scope of theappended claims and their equivalents.

What is claimed is:
 1. A heat exchanger assembly, comprising: asidebracket; a tank having at least two indentations for linking thetank to the sidebracket; and one or more isolators for flexible mountingof the sidebracket, each isolator comprising a base and a coupler thatextends from the base, and wherein for each isolator: the base of theisolator is at least partially disposed in one of the indentations ofthe tank to engage the isolator with the tank; and the coupler of theisolator extends from the base and through the sidebracket for couplingthe tank to at least the sidebracket.
 2. The heat exchanger assembly ofclaim 1, wherein the tank comprises plastic.
 3. The heat exchangerassembly of claim 1, wherein the tank comprises aluminum.
 4. The heatexchanger assembly of claim 1, wherein the tank is cast.
 5. The heatexchanger assembly of claim 1, wherein the tank is molded.
 6. The heatexchanger assembly of claim 1, wherein the coupler comprises a threadedinsert.